Quenching, Plasmonic, and Radiative Decays in Nanogap Emitting

Nov 18, 2015 - Alexey S. Kadochkin , Ivan I. Shishkin , Alexander S. Shalin , Pavel ... A. V. Chebykin , V. E. Babicheva , I. V. Iorsh , A. A. Orlov ,...
0 downloads 0 Views 1MB Size
Article pubs.acs.org/journal/apchd5

Quenching, Plasmonic, and Radiative Decays in Nanogap Emitting Devices Rémi Faggiani, Jianji Yang,*,# and Philippe Lalanne* Laboratoire Photonique, Numérique et Nanosciences (LP2N), UMR 5298, CNRS-IOGS-University of Bordeaux, 33400 Talence, France S Supporting Information *

ABSTRACT: By placing a quantum emitter in the mouths of nanogaps consisting of two metal nanoparticles nearly in contact, significant increases in emission rate are obtained. This mechanism is central in the design of modern plasmonic nanoantennas. However, due to the lack of general knowledge on the balance between the different decay rates in nanogaps (emission, quenching, and metal absorption), the design of light-emitting devices based on nanogaps is performed in a rather hazardous fashion; general intuitive recipes do not presently exist. With accurate and simple closed-form expressions for the quenching rate and the decay rate into gap plasmons, we provide a comprehensive analysis of nanogap light-emitting devices in the limit of small gap thickness. We disclose that the total decay rate in gap plasmons can largely overcome quenching for specifically selected metallic and insulator materials, regardless of the gap size. To confront these theoretical predictions, we provide a comprehensive numerical analysis of nanocube-type antennas in the limit of small gap thickness and further provide upper bounds for the photon-radiation efficiency. KEYWORDS: optical nanoantennas, spontaneous emission, nanocavity, decay rates, modal formalism, quenching

D

decay channel, what is the ultimate efficiency, and whether this limit is impacted by the gap thickness or other parameters. To further explore how optical antennas may lead to new regimes of light−matter interactions, it is important to first understand the different channel decays at play when quantum emitters in 2D nanogaps emit light in the immediate vicinity of metal surfaces and then draw a relationship between this basic situation and more complex problems of light emission and coupling with nanogap antenna architectures. This is exactly the approach that is adopted in the present work. First, we provide a comprehensive analysis of the decay rates of quantum emitters placed in 2D planar nanogaps. So far, this has been discussed only with scattered numerical calculations performed for specific gap thicknesses and metal dielectric constants.11,18,19 In contrast, we derive a closed-form formula for the branching ratio between quenching and gap plasmon decays in the limit of small gap thicknesses and then clarify the key material and geometrical parameters that drive the ratio. Counterintuitively, we evidence that the key parameters are the material permittivities and not the gap thickness and that the gap plasmon decay surpasses the quenching decay for nanogaps fed with high-refractive-index materials and molecules polarized perpendicular to the gap interfaces. Then we use the understanding gained from 2D planar structures to infer general recipes for designing efficient nanogap emitting devices. For that purpose, we model nanogap devices as gap-plasmon Fabry−Perot resonators and propose a

ielectric nanogaps in metals have an unprecedented ability to concentrate light into deep-subwavelength volumes, which has propelled their use in a vast array of nanotechnologies and research topics.1,2 For instance biological species can be manipulated at very low input powers by the field gradients at nanogaps,3 photodetectors with sizes well below the diffraction limit may be implemented with very fast response time,4 magnetic resonance supported by nanogap resonators can be utilized to realize negative-index metamaterials,5,6 and feedgaps can be used to enhance the efficiency of high-harmonic nonlinear optical processes.7 The strongly confined field also profoundly alters light emission of quantum emitters placed in the nanogap by increasing optical excitation rates, modifying radiative and nonradiative decay rates, and altering emission directionality, leading to a new generation of ultracompact nanoantenna architectures, such as bowties, spiral antennas, and phased-array antennas,8 and to new applications for light-emitting devices,9 broadband single-photon sources,10−12 single-plasmon sources,13,14 and spasers or lowthreshold nanolasers.15−17 It is generally accepted that subwavelength architectures improve the exchange of optical energy with matter by strongly increasing spontaneous emission rates. As shown by numerical calculations and experimental measurements, it is also accepted that this enhancement can be achieved with relatively good efficiencies, ∼10−60% depending on the architecture. However, the precise physical mechanisms that drive the emission of quantum emitters placed very close to metal surfaces in tiny gaps are not well understood. In particular, it is unclear from the literature why good efficiencies are achieved despite the proximity to the metal, why quenching is not the dominant © 2015 American Chemical Society

Received: July 31, 2015 Published: November 18, 2015 1739

DOI: 10.1021/acsphotonics.5b00424 ACS Photonics 2015, 2, 1739−1744

ACS Photonics

Article

Importantly, we also find that the normalized decay rate into the gap plasmon modes of the planar stack also scales as the cube of the separation distance 2d between the metal films. What happens is the group velocity vg of gap plasmons drastically decreases as d vanishes.21 Slowdown results in a strong field enhancement, and the coupling to gap plasmons is boosted. Intuitively the fact that the plasmon decay rate and quenching have identical d−3 scaling can be understood by considering that as d → 0, gap plasmons completely lose their photonic character. They are highly damped and become of the same nature as the quenching field. By using a complex continuation approach to calculate the Green tensor22 and by assuming that the transverse electric and magnetic field components of the gap plasmon bear a flat profile within the gap, we have derived an analytical expression for γGSP for very small gap thickness, γGSP ≈ 12πεd /[(2k 0d) 3|ε m|2] (see Supporting Information for details), which evidences the inverse-cubic scaling. Thus, we obtain an analytical expression for an important figure of merit of planar nanogaps with vanishing gap thicknesses, namely, the branching ratio F between gapplasmon decay rates and quenching rates:

phenomenological classification of nanogap antenna architectures, based on the trade-off between quenching, absorption, and free-space radiation rates, which may be monitored by controlling the gap-facet reflectance. To set the classification against real structures, we analyze nanogap emitting devices formed by tiny nanocubes lying on metal surfaces. By scaling down the gap thickness and the cube dimensions to keep the resonance in the visible, distinct behaviors within the same architecture family are comprehensively reviewed. Our analysis corrects inaccurate numerical results of the recent literature10,12 and definitely sets nanogaps with engineered facets as a very promising technological platform for light-emitting devices. As a final point, we summarize the main results and provide a concluding discussion.



NONRADIATIVE DECAYS IN DIELECTRIC NANOGAPS To start the analysis, let us consider the emission of a vertically polarized molecule (treated as an electric dipole) buried in the middle of a polymer layer of thickness 2d of a metal− insulator−metal (MIM) planar stack. Two channels are available for the decay. Either the molecule excites the gap plasmon modes of the planar stack or quenches by directly heating the metal. We denote by γGSP and γquench the corresponding normalized decay rates (all decay rates are normalized by the vacuum decay rate hereafter). Figure 1

F≈

γGSP 3γqSIuench

=

2εd εm(ω) + εd Im(εm(ω)) εm(ω)

2

(1)

with εd and εm denoting the dielectric and metal permittivities. The formula carries important hints: • First, the ratio is independent of d for k0d → 0, the first correction term being on the order of O(k0d)2, and takes a universal expression that depends only on the dielectric constants. • Second, for good metals, εd ≪ |εm(ω)|, one should bury the quantum emitter in a high-index material to enhance the branching ratio in the near- and far-infrared spectral regions. • Third, the ratio solely depends on the losses encountered in polarizing the material, i.e., on Im(εm(ω)), and not on the usual quality factor −Re(εm)/Im(εm) of plasmonic materials, which gives an incontestable advantage to silver at visible frequencies, in comparison with gold or aluminum for instance. Figure 2 shows typical branching ratios that can be obtained in the visible and near-infrared spectral regions with different metals and gap materials. The usefulness of the simple formula in eq 1 is reinforced by its ability to provide quantitative predictions, as evidenced with the comparison with fully vectorial computational data (shown with marks) obtained for planar nanogaps with small gap sizes (d = 2 nm). We emphasize that eq 1 is obtained in the asymptotic limit k0d → 0; as the gap thickness increases beyond the quasi-static approximation, the ratio F increases because quenching rapidly vanishes, and in this sense eq 1 actually sets a lower bound for the branching ratio. Overall, eq 1 represents a good compromise between simplicity or intuition and accuracy. In the fully vectorial results shown in Figures 1 and 2, quenching rates are found as the difference between the total decay rates (calculated as the Poynting-vector flux on a close surface surrounding the emitter) and the decay rates into gap plasmon modes (calculated using an open-source software23). Details on the calculation technique are provided in the Supporting Information along with a verification that the

Figure 1. Competition between several decay channels for a vertical electric dipole emitting in the center of an Ag/polymer/Ag gap of width 2d. The calculations are performed for an emission wavelength λ0 = 650 nm. The refractive index of the polymer is n = 1.4, and the silver permittivity is εAg = −17 + 1.15i.20 The decay rates into all channels (γtot) and gap plasmons (γGSP) and the quenching rate (γquench) are shown with black, blue, and red circles, respectively. All the decay rates are normalized by the decay rate in the vacuum.

summarizes the main trends for the decay rates for an emission wavelength at 650 nm and silver nanogaps. First we find that the direct decay in the metal, γquench, scales as d−3 as d → 0. This scaling is understood from the local and static nature of quenching. Intuitively the quenching rate in a nanogap is expected to be ∼2 times larger than the quenching rate γSI quench of the same vertical dipole on a single interface at the same 3 separation distance d, and since γSI quench = (3/8εd(k0d) )(Im((εm 19 − εd)/(εm + εd))) as d → 0, the cubic scaling is well anticipated. In fact, γquench ≈ 2γSI quench holds for d > 10 nm only; as d decreases, we found empirically with numerical calculations performed at 650 nm that the quenching rate γquench is ∼3 times larger than γSI quench. 1740

DOI: 10.1021/acsphotonics.5b00424 ACS Photonics 2015, 2, 1739−1744

ACS Photonics

Article

Figure 2. Branching ratios for nanogaps formed with various materials at visible and near-infrared frequencies. Fully vectorial calculations (for d = 2 nm) and analytical predictions from eq 1 are shown with markers and solid curves. Calculations made with Ag and Au are represented by red and blue colors, for dielectric (squares) and semiconductor (triangles) gap materials. Metal permittivities are taken from tabulated values.20

Figure 3. Classification of planar nanogap emitting devices with different degrees of decay rate enhancements. (a) Tapered devices with large photon-radiation efficiencies. Dipole emission is initially captured by gap plasmons and then adiabatically (low reflection R ≈ 0) converted into photons. Grooves etched in the metal film help conversion of launched SPPs into free-space photons. (b) Nanoresonators with controlled facet reflectivities. (c) Nanoresonators with strong facet reflectivities. (d−f) Corresponding decay rates. (d) Due to the tapering, γtot ≈ γGSP + γquench, where γGSP and γquench are the gapplasmon and quenching decay rates obtained in a planar nanogap with a thickness equal to the mouth thickness. (e) The weak reflection in (b) results in a broadband rate enhancement with a large photonradiation efficiency. (f) The strong reflection in (c) results in a narrowband Fabry−Perot resonance; γtot can be considerably boosted, but the nonradiative decay γabs due to cavity absorption lowers the photon-radiation efficiency.

indirect derivation of the quenched energy actually corresponds to the absorption in the near-field zone (70%, with large normalized emission rates, ∼103, are achieved for tiny nanogaps. Lastly, our simulations do not include additional loss mechanisms such as electron surface collisions,9 but we use silver permittivity tabulated in ref 20, which exhibits a larger amount of nonradiative losses compared to other data sets. Regardless, even if doubts remain on the exact amount of losses in metal films/particles, our calculations open important perspectives for spontaneous light emission in general and definitely set nanogaps as a relevant technological platform. The future success of the platform will depend on fabrication 1742

DOI: 10.1021/acsphotonics.5b00424 ACS Photonics 2015, 2, 1739−1744

ACS Photonics

Article

and material issues and on our ability to engineer facet reflectivities adequately.

Notes

CONCLUDING DISCUSSION Emitting photonic devices with quantum emitters embedded in nanogaps for operation at visible and near-infrared frequencies can provide large spontaneous emission rate enhancements and good photon-radiation efficiencies, because the decay into slow gap-plasmons is considerably boosted, and quenching is thus effectively overcome. This is particularly true for gaps with high-refractive-index insulators sandwiched between good metals, since the branching ratio ∝ εd/Im(εm(ω)) between gap-plasmon decay rates and quenching rates reaches values as large as 80% for semiconductor gaps operated at near-infrared frequencies. The dominant character of plasmonic decays for small gaps has a direct impact on the design and performance of nanogap emitting devices. First, the high decay rates found in planar nanogaps can be harnessed to realize tapered antennas (Figure 3a) offering strong decay rate enhancements (≈ 102− 103) and large photon-radiation efficiencies limited by the branching ratio between gap-plasmon decay rates and quenching rates; see eq 1. Second, even larger rate enhancements can be achieved in nanogap cavities (Figure 3c), which exhibit strong resonances owing to strong reflection of gap plasmons at the cavity facets. In return, the photon-radiation efficiency is significantly reduced by the cavity absorption, as indicated by the analysis of the state-of-the-art nanocube devices. Third, a better balance between decay rate enhancement and photon-radiation efficiency may be reached with nanogap antennas with engineered facet reflectivities (Figure 3b), for which a delicate engineering of the facets and a precise choice of the gap and metal materials may lead to acceleration decay rates greater than 103 with significant photon-radiation efficiency, ∼50%. Certainly, the main strength of nanogap light-emitting devices is the capability to boost the spontaneous emission rate over a broad bandwidth with potentially easy electrical contacting. This might be useful for increasing quantum yield. However, the present analysis seems to indicate that it will be hard to achieve extremely high efficiencies (∼1), as required for some quantum-information protocols, and that the branching of eq 1 appears as a barrier for the photon-radiation efficiency, which will be hard to overcome.

ACKNOWLEDGMENTS The authors thank Jean-Paul Hugonin for computational help. R.F. acknowledges financial support from the French “Direction Générale de l’Armement” (DGA).

The authors declare no competing financial interest.









(1) Schuller, J. A.; Barnard, E. S.; Cai, W.; Jun, Y. C.; White, J. S.; Brongersma, M. l. Plasmonics for extreme light concentration and manipulation. Nat. Mater. 2010, 9, 193−204. (2) Halas, N. J.; Lal, S.; Chang, W.-S.; Link, S.; Nordlander, P. Plasmons in strongly coupled metallic nanostructures. Chem. Rev. 2011, 111, 3913−3961. (3) Roxworthy, B. J.; Ko, K. D.; Kumar, A.; Fung, K. H.; Chow, E. K. C.; Liu, G. L.; Fang, N. X.; Toussaint, K. C., Jr. Application of plasmonic bowtie nanoantenna arrays for optical trapping, stacking and sorting. Nano Lett. 2012, 12, 796−801. (4) Ishi, T.; Fujikata, T.; Makita, K.; Baba, T.; Ohashi, K. Si nanophotodiode with a surface plasmon antenna. Jpn. J. Appl. Phys. 2005, 44, 364−366. (5) Valentine, J.; Zhang, S.; Zentgraf, T.; Ulin-Avila, E.; Genov, D. A.; Bartal, G.; Zhang, X. Three-dimensional optical metamaterial with a negative refractive index. Nature 2008, 455, 376−379. (6) Yang, J.; Sauvan, C.; Liu, H. T.; Lalanne, P. Theory of fishnet negative-index optical metamaterials. Phys. Rev. Lett. 2011, 107, 043903. (7) Kim, S.; Jin, J.; Kim, Y.-J.; Park, I.-Y.; Kim, Y.; Kim, S.-W. Highharmonic generation by resonant plasmon field enhancement. Nature 2008, 453, 757−760. (8) Agio, M. Optical antennas as nanoscale resonators. Nanoscale 2012, 4, 692−706. (9) Eggleston, M. S.; Messer, K.; Zhang, L.; Yablonovitch, E.; Wu, M. C. Optical antenna enhanced spontaneous emission. Proc. Natl. Acad. Sci. U. S. A. 2015, 112, 1704−1709. (10) Akselrod, G. M.; Argyropoulos, C.; Hoang, T. B.; Ciracì, C.; Fang, C.; Huang, J.; Smith, D. R.; Mikkelsen, M. H. Probing the mechanisms of large Purcell enhancement in plasmonic nanoantennas. Nat. Photonics 2014, 8, 835−840. (11) Russell, K. J.; Liu, T.-L.; Cui, S.; Hu, E. L. Large spontaneous emission enhancement in plasmonic nanocavities. Nat. Photonics 2012, 6, 459−462. (12) Rose, A.; Hoang, T. B.; McGuire, F.; Mock, J. J.; Ciracì, C.; Smith, D. R.; Mikkelsen, M. H. Control of radiative processes using tunable plasmonic nanopatch antennas. Nano Lett. 2014, 14, 4797− 4802. (13) Koenderink, A. F. Plasmon nanoparticle array waveguides for single photon and single plasmon sources. Nano Lett. 2009, 9, 4228− 4233. (14) Gan, C. H.; Hugonin, J.-P.; Lalanne, P. Proposal for compact solid-state III-V single plasmon sources. Phys. Rev. X 2012, 2, 021008. (15) Khajavikhan, M.; Simic, A.; Katz, M.; Lee, J. H.; Slutsky, B.; Mizrahi, A.; Lomakin, V.; Fainman, Y. Thresholdless nanoscale coaxial lasers. Nature 2012, 482, 204−207. (16) Oulton, R. F.; Sorger, V. J.; Zentgraf, T.; Ma, R.-M.; Gladden, C.; Dai, L.; Bartal, G.; Zhang, X. Plasmon lasers at deep subwavelength scale. Nature 2009, 461, 629−632. (17) Lu, Y.-J.; Wang, C.-Y.; Kim, J.; Chen, H.-Y.; Lu, M.-Y.; Chen, Y.C.; Chang, W.-H.; Chen, L.-J.; Stockman, M. I.; Shih, C.-K.; Gwo, S. All-color plasmonic nanolasers with ultralow thresholds: autotuning mechanism for single-mode lasing. Nano Lett. 2014, 14, 4381−4388. (18) Jun, Y. C.; Kekatpure, R. D.; White, J. S.; Brongersma, M. L. Nonresonant enhancement of spontaneous emission in metaldielectric-metal plasmon waveguide structures. Phys. Rev. B: Condens. Matter Mater. Phys. 2008, 78, 153111. (19) Ford, G. W.; Weber, W. H. Electromagnetic interactions of molecules with metal surfaces. Phys. Rep. 1984, 113, 195−287.

ASSOCIATED CONTENT

S Supporting Information *

The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acsphotonics.5b00424. (1) Indirect calculation of quenching; (2) verification of the indirect quenching calculation and localized nature of the quenched fields; (3) asymptotic expression of γGSP for MIM stacks with vanishing gap thickness (PDF)



REFERENCES

AUTHOR INFORMATION

Corresponding Authors

*E-mail: [email protected]. *E-mail: [email protected]. Present Address #

Department of Electrical Engineering, Stanford University, Stanford, California 94305, United States. 1743

DOI: 10.1021/acsphotonics.5b00424 ACS Photonics 2015, 2, 1739−1744

ACS Photonics

Article

(20) Palik, E. D. Handbook of Optical Constants; Academic Press: San Diego, 1998. (21) Yang, J.; Sauvan, C.; Jouanin, A.; Collin, S.; Pelouard, J.-L.; Lalanne, P. Ultrasmall metal-insulator-metal nanoresonators: impact of slow-wave effects on the quality factor. Opt. Express 2012, 20, 16880− 16891. (22) Collin, R. E. Hertzian dipole radiating over a lossy earth and sea: some early and late 20th-century controversies. IEEE Antennas Propag. Mag. 2004, 46, 64−79. (23) Yang, J.; Hugonin, J.-P.; Lalanne, P. Near-to-far field transformations for radiative and guided waves. 2015, arXiv:1510.06344. arXiv.org e-Print archive. http://arxiv.org/abs/ 1510.06344 (accessed Oct 21, 2015). (24) Miyazaki, H. T.; Kurokawa, Y. Squeezing visible light waves into a 3-nm-thick and 55-nm-long plasmon cavity. Phys. Rev. Lett. 2006, 96, 097401. (25) Bozhevolnyi, S. I.; Søndergaard, T. General properties of slowplasmon resonant nanostructures: nano-antennas and resonators. Opt. Express 2007, 15, 10869−10877. (26) Fernández-Domínguez, A. I.; Maier, S. A.; Pendry, J. B. Collection and concentration of light by touching spheres: a transformation optics approach. Phys. Rev. Lett. 2010, 105, 266807. (27) Yamamoto, N.; Ohtani, S.; García de Abajo, F. J. Gap and Mie plasmons in individual silver nanospheres near a silver surface. Nano Lett. 2011, 11, 91−95. (28) Mubeen, S.; Zhang, S.; Kim, N.; Lee, S.; Krämer, S.; Xu, H.; Moskovits, M. Plasmonic properties of gold nanoparticles separated from gold mirror by an ultrathin oxide. Nano Lett. 2012, 12, 2088− 2094. (29) Sauvan, C.; Hugonin, J.-P.; Maksymov, I. S.; Lalanne, P. Theory of the spontaneous optical emission of nanosize photonic and plasmon resonators. Phys. Rev. Lett. 2013, 110, 237401. (30) Bai, Q.; Perrin, M.; Sauvan, C.; Hugonin, J.-P.; Lalanne, P. Efficient and intuitive method for the analysis of light scattering by a resonant nanostructure. Opt. Express 2013, 21, 27371−27382. (31) Britt Lassiter, J.; McGuire, F.; Mock, J. J.; Ciracì, C.; Hill, R. T.; Wiley, B. J.; Chilkoti, A.; Smith, D. R. Plasmonic waveguide modes of film-coupled metallic nanocubes. Nano Lett. 2013, 13, 5866−5872.

1744

DOI: 10.1021/acsphotonics.5b00424 ACS Photonics 2015, 2, 1739−1744